1 / 42

SUPERCONDUCTING MATERIALS

0.15 0.10 0.0. Resistance ( Ω ). T c. 4.0 4.1 4.2 4.3 4.4 Temperature (K). SUPERCONDUCTING MATERIALS. Superconductivity - The phenomenon of losing resistivity when sufficiently cooled to a very low temperature (below a certain critical temperature).

dalton
Download Presentation

SUPERCONDUCTING MATERIALS

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. 0.15 0.10 0.0 Resistance (Ω) Tc 4.0 4.1 4.2 4.3 4.4 Temperature (K) SUPERCONDUCTING MATERIALS Superconductivity - The phenomenon of losing resistivity when sufficiently cooled to a very low temperature (below a certain critical temperature). H. Kammerlingh Onnes – 1911 – Pure Mercury

  2. Transition Temperature or Critical Temperature (TC) Temperature at which a normal conductor loses its resistivity and becomes a superconductor. • Definite for a material • Superconducting transition reversible • Very good electrical conductors not superconductors eg. Cu, Ag, Au • Types • Low TC superconductors • High TC superconductors

  3. Occurrence of Superconductivity

  4. Temperature Dependence of Resistance

  5. Properties of SuperconductorsElectrical Resistance • Zero Electrical Resistance • Defining Property • Critical Temperature • Quickest test • 10-5Ωcm

  6. Effect of Magnetic Field Critical magnetic field (HC) – Minimum magnetic field required to destroy the superconducting property at any temperature H0 – Critical field at 0K T - Temperature below TC TC - Transition Temperature H0 HC Normal Superconducting T (K) TC

  7. i Effect of Electric Current • Large electric current – induces magnetic field – destroys superconductivity • Induced Critical Current iC = 2πrHC Persistent Current • Steady current which flows through a superconducting ring without any decrease in strength even after the removal of the field • Diamagnetic property

  8. Magnetic Flux Quantisation • Magnetic flux enclosed in a superconducting ring = integral multiples of fluxon • Φ = nh/2e = n Φ0 (Φ0 = 2x10-15Wb) Effect of Pressure • Pressure ↑, TC ↑ • High TC superconductors – High pressure Thermal Properties • Entropy & Specific heat ↓ at TC • Disappearance of thermo electric effect at TC • Thermal conductivity ↓ at TC – Type I superconductors

  9. Stress • Stress ↑, dimension ↑, TC ↑, HC affected Frequency • Frequency ↑, Zero resistance – modified, TC not affected Impurities • Magnetic properties affected Size • Size < 10-4cm – superconducting state modified General Properties • No change in crystal structure • No change in elastic & photo-electric properties • No change in volume at TC in the absence of magnetic field

  10. MEISSNER EFFECT • When the superconducting material is placed in a magnetic field under the condition when T≤TC and H ≤ HC, the flux lines are excluded from the material. • Material exhibits perfect diamagnetism or flux exclusion. • Deciding property • χ = I/H = -1 • Reversible (flux lines penetrate when T ↑ from TC) • Conditions for a material to be a superconductor • Resistivity ρ= 0 • Magnetic Induction B = 0 when in an uniform magnetic field • Simultaneous existence of conditions

  11. Magnet Superconductor Applications of Meissner Effect • Standard test – proof for a superconductor • Repulsion of external magnets - levitation Yamanashi MLX01 MagLev train

  12. Isotope Effect • Maxwell • TC = Constant / Mα • TC Mα= Constant (α – Isotope Effect coefficient) • α = 0.15 – 0.5 • α = 0 (No isotope effect) • TC√M = constant

  13. Type I Sudden loss of magnetisation Exhibit Meissner Effect One HC = 0.1 tesla No mixed state Soft superconductor Eg.s – Pb, Sn, Hg Type II Gradual loss of magnetisation Does not exhibit complete Meissner Effect Two HCs – HC1 & HC2 (≈30 tesla) Mixed state present Hard superconductor Eg.s – Nb-Sn, Nb-Ti -M Superconducting Superconducting -M Mixed Normal Normal HC H HC2 HC1 HC H Types of Superconductors

  14. Characteristics High TC 1-2-3 Compound Perovskite crystal structure Direction dependent Reactive, brittle Oxides of Cu + other elements High Temperature Superconductors

  15. Applications • Large distance power transmission (ρ = 0) • Switching device (easy destruction of superconductivity) • Sensitive electrical equipment (small V variation  large constant current) • Memory / Storage element (persistent current) • Highly efficient small sized electrical generator and transformer

  16. Medical Applications • NMR – Nuclear Magnetic Resonance – Scanning • Brain wave activity – brain tumour, defective cells • Separate damaged cells and healthy cells • Superconducting solenoids – magneto hydrodynamic power generation – plasma maintenance

  17. Superconductivity is a phenomenon in certain materials at extremely low temperatures ,characterized by exactly zero electrical resistance and exclusion of the interior magnetic field (i.e. the Meissner effect) This phenomenon is nothing but losing the resistivity absolutely when cooled to sufficient low temperatures SUPERCONDUCTORS

  18. WHY WAS IT FORMED ? • Before the discovery of the superconductors it was thought that the electrical resistance of a conductor becomes zero only at absolute zero • But it was found that in some materials electrical resistance becomes zero when cooled to very low temperatures • These materials are nothing but the SUPER CONDUTORS.

  19. WHO FOUND IT? • Superconductivity was discovered in 1911 by Heike Kammerlingh Onnes , who studied the resistance of solid mercury at cryogenic temperatures using the recently discovered liquid helium as ‘refrigerant’. • At the temperature of 4.2 K , he observed that the resistance abruptly disappears. • For this discovery he got the NOBEL PRIZE in PHYSICS in 1913. • In 1913 lead was found to super conduct at 7K. • In 1941 niobium nitride was found to super conduct at 16K

  20. APPLICATIONSOF SUPER CONDUCTORS

  21. 1. Engineering • Transmission of power • Switching devices • Sensitive electrical instruments • Memory (or) storage element in computers. • Manufacture of electrical generators and transformers

  22. 2. Medical • Nuclear Magnetic Resonance (NMR) • Diagnosis of brain tumor • Magneto – hydrodynamic power generation

  23. JOSEPHSON DEVICESby Brian Josephson

  24. Principle: persistent current in d.c. voltage Explanation: • Consists of thin layer of insulating material placed between two superconducting materials. • Insulator acts as a barrier to the flow of electrons. • When voltage applied current flowing between super conductors by tunneling effect. • Quantum tunnelling occurs when a particle moves through a space in a manner forbidden by classical physics, due to the potential barrier involved

  25. Components of current • In relation to the BCS theory (Bardeen Cooper Schrieffer) mentioned earlier, pairs of electrons move through this barrier continuing the superconducting current. This is known as the dc current. • Current component persists only till the external voltage application. This is accurrent.

  26. Uses of Josephson devices • Magnetic Sensors • Gradiometers • Oscilloscopes • Decoders • Analogue to Digital converters • Oscillators • Microwave amplifiers • Sensors for biomedical, scientific and defence purposes • Digital circuit development for Integrated circuits • Microprocessors • Random Access Memories (RAMs)

  27. SQUIDS (Super conducting Quantum Interference Devices)

  28. Discovery: The DC SQUID was invented in 1964 by Robert Jaklevic, John Lambe, Arnold Silver, and James Mercereau of Ford Research Labs Principle : Small change in magnetic field, produces variation in the flux quantum. Construction: The superconducting quantum interference device (SQUID) consists of two superconductors separated by thin insulating layers to form two parallel Josephson junctions.

  29. Types Two main types of SQUID: 1) RF SQUIDs have only one Josephson junction 2)DC SQUIDs have two or more junctions. Thereby, • more difficult and expensive to produce. • much more sensitive.

  30. Josephson junctions • A type of electronic circuit capable of switching at very high speeds when operated at temperatures approaching absolute zero. • Named for the British physicist who designed it, • a Josephson junction exploits the phenomenon of superconductivity.

  31. Construction • A Josephson junction is made up of two superconductors, separated by a nonsuperconducting layer so thin that electrons can cross through the insulating barrier. • The flow of current between the superconductors in the absence of an applied voltage is called a Josephson current, • the movement of electrons across the barrier is known as Josephson tunneling. • Two or more junctions joined by superconducting paths form what is called a Josephson interferometer.

  32. Construction : Consists of superconducting ring having magnetic fields of quantum values(1,2,3..) Placed in between the two josephson junctions

  33. Explanation : • When the magnetic field is applied perpendicular to the ring current is induced at the two junctions • Induced current flows around the ring thereby magnetic flux in the ring has quantum value of field applied • Therefore used to detect the variation of very minute magnetic signals

  34. Fabrication • Lead or pure niobium The lead is usually in the form of an alloy with 10% gold or indium, as pure lead is unstable when its temperature is repeatedly changed. • The base electrode of the SQUID is made of a very thin niobium layer • The tunnel barrier is oxidized onto this niobium surface. • The top electrode is a layer of lead alloy deposited on top of the other two, forming a sandwich arrangement. • To achieve the necessary superconducting characteristics, the entire device is then cooled to within a few degrees of absolute zero with liquid helium

  35. Uses • Storage device for magnetic flux • Study of earthquakes • Removing paramagnetic impurities • Detection of magnetic signals from brain, heart etc.

  36. The cryotron is a switch that operates using superconductivity. The cryotron works on the principle that magnetic fields destroy superconductivity. The cryotron is a piece of tantalum wrapped with a coil of niobium placed in a liquid helium bath. When the current flows through the tantalum wire it is superconducting, but when a current flows through the niobium a magnetic field is produced. This destroys the superconductivity which makes the current slow down or stop. Cryotron

  37. Magnetic Levitated Train Principle: Electro-magnetic induction Introduction: Magnetic levitation transport, or maglev, is a form of transportation that suspends, guides and propels vehicles via electromagnetic force. This method can be faster than wheeled mass transit systems, potentially reaching velocities comparable to turboprop and jet aircraft (500 to 580 km/h).

  38. Why superconductor ? Superconductors may be considered perfect diamagnets (μr = 0), completely expelling magnetic fields due to the Meissner effect. The levitation of the magnet is stabilized due to flux pinning within the superconductor. This principle is exploited by EDS (electrodynamicsuspension) magnetic levitation trains. In trains where the weight of the large electromagnet is a major design issue (a very strong magnetic field is required to levitate a massive train) superconductors are used for the electromagnet, since they can produce a stronger magnetic field for the same weight.

  39. How to use a Super conductor Electrodynamic suspension In Electrodynamic suspension (EDS), both the rail and the train exert a magnetic field, and the train is levitated by the repulsive force between these magnetic fields. The magnetic field in the train is produced by either electromagnets or by an array of permanent magnets The repulsive force in the track is created by an induced magnetic field in wires or other conducting strips in the track. At slow speeds, the current induced in these coils and the resultant magnetic flux is not large enough to support the weight of the train. For this reason the train must have wheels or some other form of landing gear to support the train until it reaches a speed that can sustain levitation. Propulsion coils on the guideway are used to exert a force on the magnets in the train and make the train move forwards. The propulsion coils that exert a force on the train are effectively a linear motor: An alternating current flowing through the coils generates a continuously varying magnetic field that moves forward along the track. The frequency of the alternating current is synchronized to match the speed of the train. The offset between the field exerted by magnets on the train and the applied field create a force moving the train forward

  40. Advantages • No need of initial energy in case of magnets for low speeds • One litre ofLiquid nitrogen costs less than one litre of mineral water • Onboard magnets and large margin between rail and train enable highest recorded train speeds (581 km/h) and heavy load capacity.Successful operations using high temperature superconductors in its onboard magnets, cooled with inexpensive liquid nitrogen • Magnetic fields inside and outside the vehicle are insignificant; proven, commercially available technology that can attain very high speeds (500 km/h); no wheels or secondary propulsion system needed • Free of friction as it is “Levitating”

More Related